DE2728961C2 - Rotary hammer with lockable tool holder - Google Patents

Description

characterized in that

g) the toothing on the coupling part (16) than on that facing away from the drive wheel (14) Claw ring gear (16c,) arranged on the end face for the locked engagement in one on the housing (1) fixed opposing claw tooth ring (26aj is formed

2. Rotary hammer according to claim 1, characterized in that that the coupling part (16) is designed as a hollow cylinder.

3. Rotary hammer according to claim 1 or 2, characterized in that the coupling part (16) and the drive wheel (14) have claw toothed rims (16a, 14a) which can be brought into engagement with one another for mutual coupling.

4. Rotary hammer according to one of claims 1 to 3, characterized in that the coupling part (16) has an annular groove (t6b) serving to engage an eccentric cam (22a) of the actuator (21).

5. Rotary hammer according to one of claims 1 to 4, characterized in that the coupling part (16) surrounds a drive cylinder (3) assigned to the tool holder (2).

The invention relates to a hammer drill with a device for dividing the driving force into a Rotary movement for rotating the tool and in a striking movement directed in the direction of the tool axis, with a drive wheel, with a tool holder, with a non-rotatable with the tool holder connected coupling part for the transmission of the rotary movement between tool holder and drive wheel, with an actuator for the axial displacement of the coupling part from one with the drive wheel coupled position in an idle rotation position and with a toothing on the coupling part, for connection of the coupling part decoupled from the drive wheel with a toothing on the housing side.

Rotary hammers, especially those of the higher performance class, are increasingly required to that the device is also suitable for chiselling work in addition to the drill bit. It therefore applies to the one in the tool holder to impart rotary motion or rotary motion to the tool located depending on its type prevent. For reasons of problem-free handling and uniformly around the insertion ends of the tools to be able to design, it is useful if the Drehverschaitung by means of an easy-to-use device-side mechanism. Such a mechanism In particular, it is also required that the tool holder be locked when the rotary drive is interrupted or tool is possible in a desired rotary position, for example when using of a flat chisel to be able to use the device to guide the chisel appropriately for work.

In a known hammer drill, the rotary movement of a pinion driven by a motor is used transferred to a bevel gear meshing with this, which in turn is concentric on one of the Guide the piston of the hammer mechanism serving cylinder is rotatably arranged. The bevel gear has on the opposite end face of the toothing meshing with the pinion, which in turn with corresponding means of a coupling part which is non-rotatable and axially displaceable on the cylinder can be engaged. The coupling part is supported by a compression spring on the housing side held in engagement position. An eccentric handle engages on a shoulder of the coupling part Actuator, by rotating the coupling part against the spring force out of engagement with the bevel gear can be brought. The coupling part has a hexagonal casing on, against one of the six sections of the lateral surface, a surface of the eccentric is decoupled Position of the coupling part applies. As a result, the coupling part is locked against twisting and with the Coupling part together at the same time also the cylinder and the front side non-rotatably connected to the cylinder Tool holder. In the further operation of the hammer drill, the tool only needs to be Impact energy released.

This type of rotary switch-off or locking has some significant disadvantages. The hexagon of the coupling part offers the possibility of locking in only six positions. This is unsatisfactory in terms of handling. However, a more polygonal design of the coupling part is not justifiable due to the high stress on the locking surfaces of the coupling part and the eccentric handle. The hexagonal design also has the disadvantage that it occurs relatively often that the surface of the eccentric intended for locking runs onto an edge of the hexagon instead of a surface and locking is therefore only possible after the tool holder has been turned over the tool. Another negative aspect of this solution is that aie eccentric handle only decouples the coupling part, while the aforementioned compression spring is required for coupling. Apart from the disadvantage of using a large number of parts, the installation of a compression spring also requires a large overall length of the device.
Another known hammer drill (DE-OS 21 36 523) has a displaceable coupling part which is non-rotatably connected to a tool holder. To lock the tool against rotation, a locking element on the housing is in toothing engagement with

the coupling part moved. The locking element is shell-shaped and has a Radian of about ten degrees extending end face the toothing which engages with the coupling part on, so that only a few teeth are available to take over the locking force also act on one side in relation to the coupling part. This construction is therefore higher to accommodate Locking forces not suitable and has a complex structure.

According to a further known hammer drill (DE-GM 19 03 434) a coupling part is also provided, that for locking the tool in meshing engagement with a fork-like housing on the housing side Locking element is brought. The locking element has only a few teeth and again engages on one side on the coupling part, so that this arrangement is not suitable for high locking forces either

Also known is a hand tool (US-PS 26 01 788) with switchability from sawing to drilling operation. A drive motor that can be displaced into the respective functional position is used for switching Coupling part always set in rotation. A locking of the tool against twisting by fixing of the coupling part is not provided.

The invention is based on the object of a hammer drill with a locking mechanism for the tool To create chisel operations of the specified type, which are characterized by simple construction and at the same time high Excellent force absorption capacity

According to the invention the object is achieved in that the toothing on the coupling part than on that of the drive wheel facing away from the end face arranged claw ring gear for the locked engagement in a is formed on the housing firmly seated opposite claw ring gear

The rotation lock of the coupling part is achieved by the mutual interaction of all housing-side Teeth accomplished with all teeth of the coupling part. The teeth of the claw sprockets are evenly distributed over a circular path of 360 degrees so that the locking forces are evenly distributed is achieved. However, the fact that the claw ring gear on the housing side also contributes to high force absorption capacity can be incorporated directly into the housing or, for example, part of a rotationally fixed to the housing connected locking ring is.

Another advantage of this solution is that by moving the coupling part this only by the actuator, which can be, for example, a slide, in the coupled or locked Position can be brought without this having an adverse effect on the overall length Misprints required.

The coupling part is advantageously designed essentially as a hollow cylinder, for example as a sleeve. It is an extremely easy-to-manufacture part. To opposite the tool holder on the one hand to secure against rotation and, on the other hand, to achieve axial displaceability, the connection between the coupling part and the tool holder is expediently carried out by a machine element well-known key created.

In a simple and proven way, the projections or recesses on the coupling part or Form the housing by means of opposing claw sprockets. »Finding« the respective desired locking position is made easier if the flanks of the sprockets are after are tapered at the top.

The claw ring gear on the housing side can be incorporated directly into the housing or, for example, partially be a locking ring connected to the housing in a rotationally fixed manner.

Since the aforementioned type of functional connection of the coupling part and the housing is a For the transmission of large forces, it is a form-fitting coupling connection that is suitable for another Proposal of the invention useful, albeit for the mutual coupling of the coupling part and the drive wheel A further claw ring gear is provided on each of these parts for the transmission of the rotary drive is

The coupling part preferably has an annular groove which engages an eccentric cam of the actuator on. The arrangement of the eccentric cam on the actuator is chosen so that every 90 ° rotation of the actuator meshes the coupling part with the drive wheel in one or the other direction of rotation or to lock the rotary actuator & in the housing-side Claw gear engages. D: v.s actuator has for its actuation, for example, on the housing swivel head that can be operated from the outside. The individual functional positions of the final control element are included appropriately marked by locking means

It turns out to be a structurally extremely simple and advantageous solution if the coupling part is one of the Tool holder associated drive cylinder surrounds the drive cylinder can either one of the Enclose guiding the piston serving inner cylinder or take over the leadership of the piston. It is possible here to form the tool holder in one piece with the drive cylinder or, for example to create the functional one-piece structure via a screw connection. In these cases it takes over the drive cylinder transmits the torque output via the coupling part and the feather key to the tool holder or the clamped tool.

The invention is now to be explained in more detail with reference to drawings showing them for example be and that shows

F i g. 1 a hammer drill, partly in section, in the hammer drilling position,

F i g. 2 the hammer drill according to FIG. 1, in idle position,

F i g. 3 the hammer drill according to FIGS. 1 or 2, in the locked position.

The in F i g. 1 rotary hammer shown has a housing 1 with an attachment la. In the housing 1 is a Tool holder 2 via a drive cylinder 3 screwed to it on the front side by means of a ball bearing 4 and rotatably supported on the rear by a roller bearing 5. An exciter piston 6 is located on the rear side of the drive cylinder 3 out of the only indicated connecting rod 7 is set in reciprocating motion. The exciter piston 6 carries an elastic seal 6a resting on the drive cylinder 3. Located in front of the exciter piston 6 In the drive cylinder 3 there is also a percussion piston 8, which also has a sealing ring 8a.

There is a cylinder space located between the exciter piston 6 and the percussion piston 8 Air cushion, via which the percussion piston 8 also applies when the exciter 6 is executed is set in reciprocating motion. The free mobility of the percussion piston 8 is through Compensating bores 3a ensures the one hand

Ensure an outflow of the air in front of the percussion piston 8 when the percussion piston 8 is advancing and on the other hand, when the percussion piston 8 returns, outside air flows into the front cylinder space to ensure. The percussion piston 8 acts in this way on the rear end of an in the tool holder 2 introduced insertion shank 9 of a tool, which in order to achieve the rotary drive is formed hexagonal in cross section corresponding to the tool holder 2. The tool is arranged on the housing-side attachment la spring clip 11 against unwanted falling out secured from the tool holder 2.

The rotary drive of the tool is carried out by a motor-driven pinion 12, which by a ball bearing 13 is mounted in the housing 1 and meshes with a bevel gear 14. That as a bevel gear 14 trained drive wheel is on the drive cylinder 3 arranged concentrically and freely rotatable, a locking washer 15 preventing axial displacement. On the front face it has a claw ring gear 14a, which with its projections or recesses in a further claw ring gear 16a of the drive cylinder in the form of a The coupling part 16 surrounding the hollow cylinder-shaped sleeve engages. The coupling part 16 is opposite the drive cylinder 3 is slidably connected and non-rotatably connected by a feather key 17. The insertion shaft 9 thus experiences the rotational movement of the pinion 12 via the bevel gear 14, the coupling part 16, the feather key 17, the drive cylinder 3 and ultimately the tool holder 2. To between the attachment la and the Rotating tool holder 2 to achieve a proper seal is between these parts an elastic boot seal 18 is provided. Furthermore, the tool holder 2 is opposite the housing 1 supported by a further roller bearing 19 which absorbs the axial forces.

The coupling part 16 is engaged with the bevel gear by an actuator designated as a whole by 21 14 held. The actuator 21 is composed of a rotatable in the housing and limited axially displaceably mounted switching pin 22 with an eccentric cam 22a, the latter in a direction I60 deis coupling part 16 engages. The switching pin 22 is wiird with the eccentric cam 22a by a plate spring 23. which in turn is supported on a housing-side disk 24, pressed against the annular groove 16o. By just with the switching pin 22 rotatably connected swivel head 25, the switching pin 22 can be in the Bring the desired rotation position, whereby the coupling part 16 also shifts on the drive cylinder 3.

The F i g. FIG. 2 shows the actuator 21 in a manner compared to FIG. 1 position pivoted by 90 °. The switching pin 22 has shifted the coupling part 16 forwards, i.e. towards the tool, thereby pushing the Claw gear rims 14a or 16a broken out of engagement, so that the transmission of the rotary drive from the bevel gear 14 to the drive cylinder 3 or the ω Insertion shaft 9 is interrupted. The tool can be used together with the tool holder 2 and the Rotate the drive cylinder 3 freely relative to the housing 1; so it is in an idle rotation position. In In this position, only impact energy is given off to the tool when the device is in operation.

The coupling part 16 carries on the front end face a further claw ring gear 16c which with a Opposite claw tooth ring 26a of a locking ring fixedly connected to the housing 1 via a pin 27 26 can be engaged.

In Fi g. 3 is the result of further turning of the actuator 21 achieved locking position shown d. H. the coupling part 16 has been moved against the locking ring 26, so that the claw sprockets 16c and 26a mesh with one another. Even in this functional position of the In the device, the bevel gear 14 does not emit any rotational movement to the tool shank 9. Rather is the free rotation of the tool due to the positive interaction of coupling part 16 and locking ring 26 prevented. The tool acted upon by the hammer mechanism, for example a flat chisel, can thus be guided through the hammer drill in a way that is suitable for use and handling. The locking position of the The tool in the hammer drill can be arbitrarily selected by initially placing the chisel tool in the position shown in FIG. 2 shown Empty rotary position introduced into the tool holder 2 and pivoted into the desired rotary position is and then the actuator 21 in the from F i g. 3 removable locking position is brought.

For this purpose 3 sheets of drawings

Claims (1)

Patent claims: 1. Rotary hammer a) with a device for dividing the driving force into a rotary movement for turning of the tool and in a striking movement directed in the direction of the tool axis, b) with a drive wheel, c) with a tool holder, d) with a coupling part for the transmission that is connected in a rotationally fixed manner to the tool holder the rotary movement between the tool holder and the drive wheel, e) with an actuator for the axial displacement of the coupling part from one with the drive wheel coupled position in an idle rotation position and f) with a toothing on the coupling part to connect the disconnected from the drive wheel Coupling part with toothing on the housing side,